DE1214307B - Control device for positioning work machines - Google Patents

Description

Control device for positioning work machines The invention relates to a control device for positioning work machines, in particular machine tools, with the aid of periodically graded analog measuring systems, each position of the moving part of the machine corresponding to a certain time phase shift between input and output voltage, which is then determined in this way that the counting of a pulse frequency in a counter begins with every zero crossing of the input voltage and is interrupted with every zero crossing of the phase-shifted output voltage (so-called intermittent phase measurement) Location measurement can be determined. (S i mon, "The numerical control of machine tools", 1963, pp. 35 to 123.) The simplest known measuring method consists in counting continuously forwards and backwards from a certain starting position (incremental method). The starting position, which is also the zero point of the counting, can be moved to any point by deleting the counting memory. Linear scales with line grids or rotating pulse generators with optical scanning provide the pulses according to the unit of measurement. The measurement method is not absolute, as each measurement builds on the previous one; a counting error that has occurred once falsifies all further measurements. If the workpiece is machined during the positioning process, machine vibrations with amplitudes smaller than the selected unit of measurement can cause the pulse generator to emit incorrect pulses which can add up.

Avoid digital absolute standards or code disks in well-known Wise the disadvantage of the incremental method by dividing it into units of measurement Trace of all high-order digits traces are added. The dimensions are represented in a yes / no code by a grid; they are unique to each place assigned. The risk of inaccurate reading at the edges of the grid fields is caused by encountered special design of the reading process (V-brush arrangement) or the code (Gray code). All dimensions refer to a fixed zero point, the start of the scale. Compared to the pure counting method, the effort is higher.

An analog measurement of the local value with the aid of resolvers is also known. A resolver is a transformer in the form of a small electrical machine consisting of a stator and rotor. The stator has three windings spatially offset by 120 '. The single-phase rotor winding is rotated by the moving machine part. The voltage induced in the rotor winding becomes electrically to zero after an angle of rotation of 1801 each , so that the path covered by the machine part is mapped analogously. By combining several resolvers via measuring gears with a suitable transmission ratio, a long distance can be mapped clearly and with a high resolution. (Mayer, "Introduction to the technology of numerically controlled machine tools, 1963, pp. 15 to 17; magazine." Industrie-Anzeige, r ", 1963, No. 63, pp. 1496 to 1498.) One avoids the disadvantage of this rotating system High accuracy inductive scale in which the windings are applied to a linear scale in the printed circuit. The insulated material used for machine construction can be used as the carrier plate, so that errors due to uneven thermal expansion between the scale and the machine are eliminated.

It is known that such absolutely operating measuring systems can be used to specify the local setpoint value supplied by the paper tape in digital form as a voltage by means of transformers with decadic steps (US Pat. No. 2,875,390 ). At the output of the comparison device, the deviation between the specified nominal value and the position of the machine is available in the form of a voltage. When moving into the position, the coarsest measuring system first issues the command. When the moving machine part approaches the programmed local setpoint, a switch is made to the middle system and then to the fine system. It is not possible in this case to determine the actual deviation of the respective position of the machine part from the specified position without great effort, so that the necessary switching points for the speed reduction when retracting are subject to a certain spread and thus the retraction process is slowed down. ("Siemens-Zeitschrift", 1961, no. 8, pp. 570 to 572.) It is also known to convert the respective analog value of a measuring system into a digital value with the help of a constantly repeated (intermittent) phase measurement. (Suesskind, "Notes on Analog-Digital Conversion", 1958, pp. 6 to 9.) The object of the invention is, with such an intermittent phase measurement, in which a number of pulses proportional to the phase shift is counted into a counter, the in the case of analog measuring systems with periodic graduation, previously known devices to be improved both economically and technically. This object is achieved according to the invention in that the setpoint position value for each of the measuring systems which successively determine the counting into the counter is preset in the counter, which is cleared before each measuring process, and the measuring result is transferred to a memory. In this way, a control device can be set up in which the intermittent phase measurement is carried out alternately in the individual measuring systems and in which the deviation from the specified target position value is also immediately available by presetting the counter in the memory. This also eliminates the need for complex digital difference formation between setpoint and actual value. In contrast to purely digital measuring systems, the actual position can be determined again immediately after the voltage has returned after a power failure. Furthermore, the counter for counting in the coarser measuring system is only released when a pre-counting result obtained with the value of the highest decade of the finer measuring system has reached zero by the coarser measuring system associated pulses. In this way, the errors that occur in the coarser measuring systems as a result of the digitization of the measured values can be avoided. The counter is also advantageously constructed in the manner of a shift register and is connected to the inputs of a difference calculator with a preset zero-point shift register for comparison by decade. In this way, every position of the machine can be explained to the zero point, despite the analog measuring system. The zero point shift register can then be preset for the zero point shift and / or cutter radius compensation by means of a decade switch by hand or from a punched tape. In this way, simple dimensional corrections can be entered in the machine control.

The invention is explained below with reference to the drawing using an exemplary embodiment: From the drawing, a position measuring device with three analog measuring systems A, B, C with a periodic gradation of z. B. 1: 100 can be seen, the measured values of which are digitized. Each this- measuring system consists of two coil arrangements, one of which, which the working machine is permanently assigned to the one (1, 3.5) represents a scale, while the other coil arrangement (2, 4, 6), as indicated by dashed lines, with the Moving part of the machine connected and is movable relative to the first coil assembly. The movable coil arrangements consist of two coils electrically offset by 90 ' , which are supplied by a sine wave generator 7 with a frequency of, for example, 2 Idb with voltages phase-shifted by 900. The phase shift by 90 ' is achieved by means of a phase shifter 8 . This feeding of the movable coils creates a moving field in each of the measurement orders A, B, C , which induces sinusoidal voltages in the associated fixed coils. The temporal phase position of these induced voltages is dependent on the respective position of the movable coils. Such a measuring system, which in principle works like a resolver, is known.

The generator 7 supplying the sinusoidal voltage is synchronized by means of a reducer 10 from a quartz oscillator 11. This crystal oscillator 11 has a much higher frequency than the sine generator 7, for example 2 MHz. In addition to the movable coils of the individual measuring systems, the sine generator is now also connected to a flip-flop 12. In addition, the fixed coils of the individual measuring systems are each connected to further flip-flops 13, 14, 15 . These flip-flops have the property of changing their output voltage abruptly when the input voltage reaches certain threshold values. These flip-flops can be blocked as required by appropriate signals on the individual lines a 1, b 1, c 1.

The output of the flip-flop 12 is connected to the set input and the outputs of the flip-flops 13, 14, 15 are connected to the clear input of a memory 16 . The memory 16 is, together with the QuarzosziRator 11 to an AND gate 17. This AND gate 17 is once about a pre-count 18 and the other connected directly to a further AND gate 19, which in turn leads to a further counter 20th The counter 20, in which the respective setpoint values for the individual measuring systems from a setpoint generator 30 were previously used, is counted down by the pulses reaching the counter 20. As indicated, 20 may be made a carry of a decade in the count 18 of this counter. The counter 20, which is expediently designed as a shift register, is connected to the inputs of a difference generator 22 together with a zero point shift register 21. The output of this difference generator is connected to the fine memory 24, the central memory 25 and the coarse memory 26 . The value present in these memories 24 to 26 is fed to a display tube 27 and used via a digital-to-analog converter 28 and amplifier 29 to control the drive motor 9 of the moving part of the working machine.

The mode of operation of the control system according to the invention is explained below: For measurement in fine system A , flip-flop 13 is enabled by a signal on line a 1 . The flip-flop 14 and 15 and thus the measuring systems B and C remain blocked. When the sinusoidal voltage supplied by the generator 7 crosses zero, the flip-flop 12 responds. The memory 16 is set by its output signal, so that a signal appears at its output. As a result, the AND condition for the AND gate 17 is fulfilled, so that the pulse frequency of 2 MHz coming from the generator 11 is counted into the counter 20. The function of the precounter 18 and the AND gate 19, which are not considered here, will be explained later. If the voltage induced in coil 1 goes through zero, flip-flop 13 responds. The memory 16 is erased by its output signal and thus the AND gate 17 is blocked for the pulses supplied by the generator 11. The counting result present in the counter 20 is a measure of the deviation of the moving machine part from the zero position within the period. To compare the setpoint and actual values, the three lowest decades from the setpoint memory 30 are inserted into the counter 20 before the start of the measurement process. As a result, the reference point within the period is shifted according to the set number in relation to the absolute zero point of the period. After the countdown process has ended, there is then a value in the counter 20 which corresponds to the difference between the setpoint and the actual value of the fine dimension. This value is entered into the fine memory 24. The difference generator 22 and the zero point shift register 21 are not taken into account here.

The above-described measuring process is now carried out in the same way for the center track B and then for the coarse track C > the counter 20 being preset in each case by the decade setpoint corresponding to the respective track. The values occurring in this counter 20 are then transferred to the memories 25 and 26 respectively after the measurement processes have ended.

Thus, after three measurement processes, the deviation of the machine position from the specified nominal value is available in the memories 24 to 26. It was assumed here that the reference point from which the nominal value was measured corresponds to the absolute zero point of the measuring systems.

In the present embodiment, it is assumed that the digitization of the values supplied by the measuring systems can be carried out with an accuracy of ± 0.5 () / o. However, since the quantization step is 1 %, this would lead to difficulties in the medium and coarse systems if a value in the vicinity of 5 to 9 is present in the fine system or in relation to the coarse system in the medium system. This roughly corresponds to the difficulties encountered with digital absolute measuring systems. In the device according to the invention, a pre-counter 18 is switched on between the AND gate 17 and the counter 20. In this pre-counter, which consists of a decade, the third decade of the measurement result is transferred in the fine system when measuring in the mean system. At the beginning of the counting process in the central system, i. H. When the AND gate 17 is released, the pulses first enter the pre-counter 18. The counter 20 is initially blocked for the pulses, since the AND condition at the AND gate 19 is only met when the pre-counter 18 is zero. The pre-counter 18 is therefore first counted down to zero, and only then does the counting into the counter, 20. This corresponds to a shift of the reference zero point by 0 to 9 units for the subsequent counter. This enables a clear and reliable measurement in the coarse tracks.

In general, the absolute zero point of the measuring system cannot be used as a reference point when machining a workpiece. A zero point shift is therefore necessary. To determine the zero point shift, the machine is moved to the desired position, the setpoint memory 30 is set to 0 and the measuring process is carried out for this point. The result displayed in the memories 24 to 26 corresponds to the shift of the reference point with respect to the absolute zero point. This value is saved with the aid of decade switches 23.

If the machine position does not coincide with the reference point, but the deviation between the reference point and the existing machine position is known (turning a surface or crosshairs for the tool tip), this value is entered in the setpoint memory 30. As a result, the position of the reference point can also be determined by the measuring process. The zero setting of the reference point stored in the decade switches 23 is then transferred in parallel to the zero shift register 21.

When the measuring process for the fine track A has ended, the counter result is not transmitted directly to the fine memory 24, but via the difference calculator 22. The difference is formed in a series operation, with the last decade of the counter 20 and in the form of a shift register those of the zero shift register 21 are pending at the difference former 22. The result of the difference formation is transferred to the last decade of the fine memory 24.

Then comes a shift clock T for the counter 20 and at the same time the zero shift register 21, so that the penultimate decade is sent to the subtractor 22 pending. The result is then entered in the fine memory 24 in the penultimate position used. This process is repeated for every decade, so that after a measuring process the zero shift register is empty for all three tracks.

For each new measuring process, the values stored in the decade switches 23 are again transmitted. The measuring and calculating process can be carried out relatively quickly. For example, with a generator frequency of 2 kHz and three measuring systems, a measuring sequence of 3 to 4 ms can be expected.

The device according to the invention can also be used for actual value measurement in relation to the absolute measuring system zero point or in relation to the respectively selected reference zero point which is determined by the decade switch 23 . During this measuring process, the counter 20 is not preset by the setpoint memory, so that the actual position minus the zero setting is available in the memories 24 to 26 and can be displayed. The device according to the invention can be used for several axes at the same time, with the respective setpoint value for the coordinate in question being entered into the setpoint memory and the zero shift for this coordinate transferred to the zero shift register. A decade switch arrangement is therefore necessary for each coordinate.

Loading by adding further decade switch is also the possibility to perform a measurement correction, and in each decade switches of the respective calibration value for the respective tools, d. H. the zero offset required for this is saved.

In addition, the device according to the invention can be used to compensate for the cutter radius be carried out in the same way. In this case, however, the difference generator must then 22 can optionally also carry out an addition process.

The control device according to the invention can be constructed in a completely contactless manner be. The measuring systems used can also be used for path control will.

Instead of the measuring system described in the exemplary embodiment can also use resolvers in conjunction with an appropriately stepped transmission gear step.

Claims (2)

Claims: 1. Control device for positioning work machines, in particular machine tools, with the help of periodically graded analog measuring systems, each position of the movable part of the machine corresponding to a certain phase shift between input and output voltage, which is then determined in such a way that the Input voltage, the counting of a pulse frequency begins in a counter and is interrupted at each zero crossing of the phase-shifted output voltage, characterized in that the setpoint position value for each of the measuring systems determining the counting in the counter is preset in the counter, which is cleared before each measuring process, and the measuring result in each case in one Memory is transferred. 2. Device according to claim 1, characterized in that the counter for counting in the coarser measuring system is only released when a pre-counter preset with the value of the highest decade of the measurement result obtained in the finer measuring system has reached zero through the pulses associated with the coarser measuring system . 3. Device according to claim 1, characterized in that the counter is constructed in the manner of a shift register and is connected to the inputs of a difference calculator with a presettable zero-point shift register for comparison by decade. 4. Device according to claim 1 to 3, characterized in that the zero point shift register for zero point shift and / or cutter radius compensation can be preset by means of a decade switch by hand or from a punched tape. Referred to U.S. Patent No. 2,875,390; Simon, "The numerical control of machine tools", 1963, pp. 35 to 123; Mager, "Introduction to the Technology of Numerically Controlled Machine Tools", 1963, pp. 15 to 17; "Industrie-Anzeiger" magazine, 1963, No. 63, pp. 1496 to 1498, "Siemens-Zeitschrift", 1961, issue 8, pp. 570 to 572; Suesskind, "Notes on Analog-Digital Conversion", 1958, pp. 6 to 9.